Apparatus for forming and projecting a foam mixture



March 3, 1953 c. R. FOUTZ 2,630,183

APPARATUS FOR FORMING AND PROJECTING A FOAM MIXTURE BY 33 I 33 ATTORNEY March 3, 1953 c. R. FoUTz 2,630,183

` APPARATUS FOR FORMING AND PROJECTING A FOAM MIXTURE Filed Jan. 26, 1950 3 Sheets--Sheefv 2 il l,"

INVENTOR.

E l'nitm En nt Fui vz',

ATTORNEY March 3, 1953 c. R. FouTz 2,630,183

APPARATUS FOR FORMING AND PROJECTING A FOAM MIXTURE Filed Jan. 2e, 195o s :ineens-Shayv 5 ATTORNEY Patented Mar.. 3, 1953 UNITED STATES PATENT GFFICE APPARATUS FOR FORMING AND PROJECTING A FOAM MIX'IURE 9 Claims.

This invention relates to a method and apparatus for forming and projecting a foam mixture, particularly for use with fire-lighting apparatus. This application is a continuationin-part of application Serial No. 782,592, filed October 28, 1947, now abandoned.

The use of a foam for sinothering and extinguishing fires is well known, but this use has been limited in application due to the fact that known foam-forming methods and apparatus are incapable of projecting the foam. According to these prior art methods and devices, the foamforming ingredients, usually water, air and foamforming liquid such as liquid soap, are all intermixed under pressure with a high degree of turbulence to form the foam which is fed out by the pressure in the mixing. chamber. Furthermore, the use of air in the foam is unsatisfactory due to the expansion and breaking of the foam bubbles Which provide oxygen right at the burning surface to feed the flames. Consequently, the foam merely flows from the apparatus and must be applied directly to the burning surface and this defect, despite the use of asbestos suits and other protective devices, limits the use` of foam to relatively small conflagrations.

Having in mind theA defects of` the prior art methods and apparatus, it is an object ofY the present invention to provide a method of and an apparatus for producing a foam mixture thatmay be projected in the. same manner as a liquid; that producesv a foam from a` mixture without mechanical turbulence but solely by natural forces through dispersion and homogeneity due to different thermal and physical characteristics such as density, Viscosity and adhesion; that provides a foam that will adhere to and smother a burning surface; andk that has simplicity of design, economyv of construction and efficiency in operation.

The foregoingv objects and others ancillary thereto are preferably accomplished by the production of a concentrically laminar' rod of iiuid mixtures having a core of water under axial pressure with cylindrical lamina of the other ingredients. In a fire-fighting foam, this laminar rod will comprise at least a core of water projected under pressure, a surrounding sleeve of foam liquid such as liquid soap, and an outer sleeve of a hot gas which is devoid of free oxygen. This laminar fluid rod is capable of being projected and forms, through natural forces, a homogeneous colloidal foam mixture wherein the bubble-entrappedy gas will not feed theI re and, in addition', will contract, rather than expand, and thereby increase the surface tension of the bubbles.

This laminar fluid rod is most conveniently produced by an apparatus, in accordance with the present invention, which comprisesA at least two axially disposed veni-contracta throats, the second throat being slightly larger than the. rst and each having an auxiliary inlet. When water is pumped through this apparatusat suicient pressure and velocity, it creates a vacuumV at' the auxiliary inlets to draw in other fluids, such as a foam-forming liquid through thev inlet of the first throat and gasthrough the inlet of the second throat.

The novel features that are considered characteristic of the invention are set forth with particularity in the appended claims. The invention itself, however, both as to its organization and its method of operation, together with additional objects and advantages thereof, will best be understood from the following description of specific embodiments when read in connection with the accompanying drawings, wherein like reference characters indicate like parts throughout the several figures and which:

Fig. 1 is a view in cross-section taken longitudinally through a basic form of the device in accordance with the present invention;

Fig. 2 is a view in cross-section taken on line 2 2 of Fig. 1,;

Fig. 3 is a view in cross-section taken longitudinally through a modied form of the device;

Fig. 4 is a view in cross-section taken onV line li--d of Fig. 3;

Fig. 5 is an end view of the inlet end of the modification shown in Fig. 3;

Fig. 6 is a view in cross-section taken longitudinally through a preferred modification and commerical adaptationA of the device;

Fig. 7 is a fragmentary view in cross-section taken longitudinally of al device4 incorporating a modification of the device shown in Fig. 51;

Fig. 8 is a view in cross-section taken onA line 8--8 of Fig'. 7;

Fig. 9 is an inlet end view of the device with a self-powered foam liquid injector operatively coupled thereto and shown incross-section;

Fig. 10 is a side view of theA device and injector shown in, Fig. 9, with the inlet end of the device in cross-section; and

Fig. 11 is a diagrammatic cross-sectional view of the device in operation and illustrating the method for forming the assembly ofv fluids.

Referring now to the drawings, specically to Fig. 1, a device incorporating a basic construction in accordance with the present invention, comprises an upstream Veni-contracta A and a downstream veni-contracta B, each conveniently formed as a separate member or casting and rigidly secured together. The veni-contracta A comprises a Venturi tube having an upstream cone 2 open to an inlet I and contracting to a throat 3 which opens into a downstream cone 4. An auxiliary inlet 5 opens into the Venturi tube substantially between the throat 3 and downstream cone 4, and an annular shell or casing 6 surrounds the downstream cone 4 and has an inlet 'I. The veni-contracta B comprises a closed Venturi tube having an upstream cone 8 open to and secured at its leading edge to the casing 6 and contracting to a throat 9 which opens into a downstream cone I that expands to an outlet I I. An annular baille plate I2, having openings I3, in the present instance, is sandwiched between thc casing 6 and the upstream cone 8 to circumferentially distribute ow from the inlet l, around the chamber formed by the casing 6 and to the cone 8.

In operation, brieiiy the device may be connected with the inlet I open to a supply of fluid under pressure, such for instance as water. Sources of other fluids, not necessarily under pressure, are connected respectively with the inlets 5 and 1. When the water supply is rst opened, the water flows into the inlet and fills completely both of the Veni-contractas A and B, displacing all air therefrom, after which the water pressure is increased so that the water is constricted by the throat 3 and projects therefrom as a solid rodlike stream of water, the pressure of the water causing the sides of the stream to fall away from the walls of the downstream cone 4, in which a very low absolute pressure is created through the inlet 5. The second fluid is then drawn through the inlet 5 and surrounds the rod of Water. Substantially the same action occurs in the Venicontracta B. The iiuid rod of water surrounded by the second fluid streams from the cone 4 through the throat 9, lowering the absolute pressure there, leaves the converging walls of the downstream cone I0, thereby causing a suction through the upstream cone 8, chamber 6 and inlet "I, drawing in a third fluid which is circumferentially spread by the baffle I2 to surround the fluid rod as a second cylindrical lamination. Preferably, at least two of the fluids differ in characteristics of travel speed, viscosity, density and the like, so that as they project from the Veni-contracta B, there is an interaction between the core and adjacent laminations that eventually results in a homogeneous stream, without decreasing the force of the stream as occurs by induced mechanical turbulence.

The basic device, as shown in Fig. 1, may be modified in various ways to accommodate the inclusion of additional laminations to the fluid rod, an increase of agitation of the fluid, or adjustment of the device to vary the intake of fluids. One modiiication is shown in Fig. 3 wherein the veni-contracta A is substantially identical to that previously described but the veni-contracta B is somewhat modified as it comprises a housing I5 which contains the upstream cone 8 contracting to a terminal throat 9. A second upstream cone I6 is spaced from throat 9 and contracts to a terminal throat I'I. The housing I5 terminates in an upstream cone I8 which contracts to a throat I9 that terminates in the outlet II. The housing I5 defines a chamber 20 with which the cones I6 and I8 are in communication. An inlet 2I is provided in the housing I5 and opens into the chamber 20 so that a fourth fluid may be drawn in by the low pressure diierential created by the iiuid rod passing through the cones I6 and I8, thus forming a third double layer cylindrical lamina around the fluid rod. If this fourth fluid is not desired, the inlet 2I may be closed by a plug 22.

The cone I6 may be axially supported by spokes 23 extending to the housing I5. The mixing of the laminar fluid rod may be expedited. if desired, by providing one of the throats, the throat I'I in this instance, with inwardly curved projections 24 which will deflect portions of the iiuid rod and instigate streamline dispersion without turbulence so that the force of the stream is not materially reduced. Furthermore, diametrical or other longitudinally extending vanes 33 may be mounted in the inlet I to streamline the iiow of the water and baffle any turbulence that may be caused by a butterfly or like valve that is only partially open.

Another modification, and the preferred form of the device, is shown in Fig. 6. In this form, the veni-contracta A comprises two parts, the primary member 25 including the main inlet I, upstream cone 2, throat 3', and casing 6. This part 25 has an internally threaded annular recess 26 surrounding the elongated downstream end of the throat 3 for the reception of a threaded annular extension 21 of the secondary member 28 which contains the downstream cone 4. An inlet 5a extends through the primary member 25 and opens into the inner end of the recess 26, and the inner annular wall of the recess 26 and inner wall of the annulus 28 are radially spaced to define a through annular passage 5b from the inlet 5a to an annular discharge opening 5 between the throat 3 and the cone 4'.

The downstream end of the secondary member 28 is rotatable and provided with lugs 29 for cooperation with a suitable tool insertable axially through the Veni-contracta B to thread the annulus 21 relative to the recess 26 for adjusting the opening 5 to regulate iiow therethrough. Obviously, this operation is limited to an initial adjustment before each operation and if adjustment during operation is desired, a more expensive construction may be employed such, for example, as that shown in Fig. '7.

According to the arrangement shown in Fig. 7, the secondary member 28 is surrounded by a spur gear 30, in mesh with a pinion 3| which is xed on a shaft 32 that is journalled in and extends through the annular casing 6 and carries a hand knob 32 at its outer end. By manual adjustment of the knob 32', the pinion 3| will rotate the spur gear 30 and thread the annulus 21 relative to the recess 26 and thereby adjust the annular opening 5. Preferably, the spur gear 30 is ixed to the member 28' and is relatively wide to accommodate axial mov-ement with respect to the pinion 3I.

The baiile plate I2 is preferably modified to comprise a solid plate having an inner edge that is spaced from the outer surface of the member 28 to define an annular passage I3. As the plate I2' is removably sandwiched between the venicontractas A and B, it may be replaced to provide a passage I3 of desired dimensions. The annular passage I3 is preferred as it is operative to form the fluid passing therethrough in a cylindrical mass rather than in a plurality of individual str-cams as produced by the apertures I3 in the perforated plate I2.

The veni-contracta B also comprises twoparts, an inner member 35, which defines the upstream cone 8 and terminal throat 9', and an outer member 36 which comprises a Venturi-like tube having an upstream cone 31, throat 38 and downstream cone 39 which opens to the outlet Il. If desired, the inwardly curved projections 24 may be provided in the member 36, and in addition the upstream cone 3l may be provided with an inlet 2i for the admission of another uid or as a drain for residual liquid Iand closed by a plug 22 as hereinbefore described with relation to the modification shown in Fig. 3. It will be noted that the dimensions of the throat 38 and downstream cone 39 are in such relation to the throat 9' as to define a phantom downstream cone I0 fm1 the throat 9.

A further modification is illustrated in Figs. '7 and 8, wherein it will be seen that the downstream cone 4 4 is provided with a plurality of fins 34 which are in parallel with each other at their inner faces, that is the inner faces are cylindrical or tangent to the cylinder of the water rod forward streamline ow. The height a, of the downstream ends of the fins, is equal to the sine of the angle of the downstream necessary divergence of about 3- and the width b is made as small as possible considering the structural strength necessary. The purpose of the fins 34 is twofold: First, to increase the inside surface area of the cone d to which the water first and then the foam-forming liquid may adhere; and, second, to control and secure better envelopment by the foam-forming liquid around and over the circumferential surface of the water column.

As previously stated, when initially starting the use of the device, the water should be admitted under low pressure in order to completely ll the downstream cone 4 4' and drive lall of the air therefrom, after which the pressure is increased to cause the water to project from the throat 3 3 in a rod-like stream. As the pressure is increased and the water draws away from the diverging walls of the cone 4-4' it creates a vacuum or a lower differential pressure and sucks the foam liquid in through the inlet 5 5.

In practice, however, it has been found that the tendency is to turn the water on full force, or at least at toohigh a pressure, so that the Veni-contracta A acts as a nozzle and the. water is immediately projected through the cone 4 4 in a rod-like stream so that the air is not displaced therefrom. Consequently, no suction is createdv in the auxiliary inlet 5-5, and the foam liquid is not drawn into the inlet but, if anything, is forced back by the increased air pressure. In this event, the water pressure must be reduced and the operation started all over again.

The foregoing difficulty may be obviated and the initial starting speeded up by a self-poweredl foam liquid injector that is actuated by the water pressure and shown in Figs. 9 and l0. The injector mayl comprise a by-pass passage 50, including a drain cock 5 I, that opens into the inlet I-I', to be open to the water pressure therein,-

and extends for communication with a double cylinder 52 that is supported byv a bracket 53 mounted on a base 54 formed on the housing 25 of the Veni-contracta A. The double cylinder 52 comprises a high pressure cylinder 55 and a low pressure cylinder 56, the cylinder' being, preferably, axially aligned and having an opening 51 therebetween with. a gasket 58 surrrounding the opening` 51 on the low pressure side thereof. A double piston 59 is mounted in the double cylin der 52 and includes a high pressure piston 80 in theA cylinder 55, a low pressurel piston 6I in the cylinder 56 and a rod 62 extending through the opening 51 and rigidly connecting the pistons. A conical collar 63 is fixed in back of the piston El and around the rod 62 to cooperate with the gasket 58 in forming a tight seal when the piston 6l is retracted.

A needle valve 64 is carried by the piston 6| to cooperate with a needle valve seat 65 formed in the end of the cylinder 56 and terminating in an orifice 66 which opens into the center branch of a T connection 61. A supply line 68 is connected from a source of supply to one branch of the T 61 and a feed line 69 extendsl from the other branch of the T 61 for connection with the auxiliary inlet 5a of the Veni-contracta A. A nonreturn check valve 1l) is inter-posed in the supply line 68 to prevent return to the supply, and a non-return check valve 'Il is interposed in the feed line B9 and a manually controlled valve 12 is also interposed in the feed line 69.

The by-pass is connected in open communication to the inlet I-l and consequently to the water-gate or butterfly valve of the pump and receives the high pressure water when the watergate is suddenly opened. Powerful vector forces thus may be set up before the angularity of the water passing out of the gate valve may be restored to parallel laminar flow before reaching the upstream throat 2-2 without which sufficient pressure drop mightv not be obtained to cause the foam-forming liquid to enter through the inlet 5-5, at or below atmospheric pressure. When the water-gate is jerked open and water enters the inlet |--I", a small volume will be forced into the by-pass and flow into the high pressure cylinder under the water piston 60 which is always at its lowest position and nearest to the entering water stream before every start. Likewise the low pressure piston 6I is necessarily at its lowest position, both being connected by the common piston rod 62. When in injecting position for foam-priming, the cylinder cubage in cylinder 5.6, above the piston, isfilled with the foam-forming liquid.

When the foam liquid control valve 12 is opened, while the water is being discharged through the veni-contracta throat 2--2",` the pressure of the water in the inl'etj l-l will be transmitted into the cylinder '55 and will force the water piston -50 forwarder upward. This high pressure will drive the piston 6i upwardly and force the foam-liquid in they cylinder 56 above the lowv pressure piston 6I, ou-t of the low pressure cylinder 56, through the needle valve 64 and seat I out through the orifice 66 and T |6'! into the foam liquid lpipe line `69 through which the foam liquid is forced at any desired pressure above atmosphere into the inlet 5 5. The nonreturn check valve 10 prevents the foam liquid from flowing back from the cylinder 5B into the foam liquid supply line 68 during the injection period, which may `be made a short or longtime, as desired, by control of the foam liquid cylinder cubage and size of the needle valve discharge orifice 65 and the relative piston areas.

The high water pressure on piston 50 pushes the piston 6l on -to its needle valve seat, where it is held until ythe water-gate is closed, thereby restoring the pressure to atmospheric. After the low pressure piston has discharged', above atmospheric pressure, the cylinder volume, of foam liquid and. held onA its needle valve seat'. the pressure drop in the throat 3`3"', cone 4-4" and 7 inlet 5 has changed to below atmospheric with sufiioient pressure differential to cause the foam liquid to flow continuously thereinto. Every time and wherever the water-gate valve is closed or the Ipump stopped, both pistons 60 and `I will move to their respective lower or rear end positions which will cause the `foam lliquid to fiow into and fill the low pressure cylinder 50 with foam liquid until the piston 6I is seated on the conical seat `63 and gasket 58. The non-return check valve 'II excludes the -entrance of air during the cylinder filling and entrance of water due to accidental stoppage of the colloidized stream in the hose line as could occur by a falling wall or heavy vehicle lpassing over the hose line behind the discharge nozzle.

The travel of piston 60 is such that at `both ends there is sufficient clearance space so that the piston 6I will always seat tightly without leaking at either end of its stroke. This water pressure foam liquid priming injector is entirely automatic and Idischarges with the opening of the water gate if the water pressure is above the necessary maximum, and recharges with foam liquid upon the closing of the water gate. If necessary, the foam liquid may be manually supplied to the cylinder 56 by means of a plug-closed opening in the top or the T161, having first turned off the valve I2 which is kept closed at all times until the foam liquid is needed.

The basic device has many uses, but its most advantageous use, at the present time, is in conjunction with fire-fighting apparatus for producing a colloidal foam mixture without materially affecting the velocity of the fluids so that the foam mixture may be thrown from a fire hose in much the same manner -as water alone. Within its linear length the device contains the means for creating material sub-atmospheric pressure changes by creating different flow velocities in -the column of water in transit through the apparatus from its inlet I, connected to the discharge side of an internal combustion engine pump (with the gas inlet 'I connected to the engine exhaust), through the last veni-contracta throat Ill-I0 and its outlet I I into the fire hose and nozzle with which the outlet end is connected.

The operation of the device is best illustrated in Fig. 11, wherein it will be seen that the ulpstream cone 2 of the first and true veni-contracta A is formed as a hyperboloid to contract the Water to the throat 3-3 diameter without turbulence or swirling and to maintain it in streamline flow through the slightly diverging downstream cone 4-4' until a desired certain velocity is attained, when it breaks loose to form a rod R of water. Before breaking free of the cone 4-4 a vacuum is created which sucks in the second fluid, thus lling the space with a foamforming liquid such as protein oils, soap, or mechanical foam-forming liquid. This liquid forms a cylindrical sleeve X which envelops the rod-like stream R of water as it projects through the cone 4 4'.

The downstream cone 4 4 projects through a sharp edge metering Ibaffle plate l2-I2 which is placed between the gas inlet chamber 6 and the upstream cone 8 of the gas Veni-contrasta B. The annular passage or opening I3 thus formed is for the purpose of spreading evenly and streamlining the gas flowing to `and over the liquid surface and fiow with it through the second or gas upstream cone 8 to form another R-X. Bv this prevention of gas turbulence, the exhaust gas has the same directional flow as the liquid stream and envelops it entirely without breaking the surface lm laminar flow continuity or the laminar streaming because the highly polished smooth interior or wetted surface prevents impact shock with vector formation that would result from rough surfaces.

The gas upstream cone 8 projects into a third upstream cone 3l with a throat 38 through which the two liquids and gas all pass in streamline fiow. Still another fluid may be added at this point, admitted through inlet 2 I, to form a laminar sleeve Z, but such additional fluid is not normally included in producting a fire-suppressing foam. All the fluids are now brought under the same absolute pressure but because of volumetric difference and densities, the dispersion of the gas in bubble formation throughout the streaming water takes place. The formation of the gas spheres originates on and in penetrating the liquid soap nlm enveloping the water column, under the pressure created by the large volume of the gas entering with the two liquids into the outlet II which has exactly the same transverse area as the inlet I that was occupied by the water alone.

This means that 16 unit volumes of Water and soap liquid meet 100 unit volumes of gas and together traverse through the same cross-sectional area through the fire hose to the discharge nozzle. The expanded hot and contracting gas is forced through the enveloping laminar liquid soap film and into the stream of water without disruption or discontinuity of the water stream which, because of its high velocity mass force, remains in streamline formation. The water stream receives the foam liquid gas-soaked bubbles practically without variation in linear speed, but at different momentum, thus effecting their dispersal and uniform separation. This action effects complete and homogeneous dispersion throughout the water column streaming in laminar flow at high velocity and without vortices or turbulence caused by angular forces or baffles, from entry of the first veni-contracta A to exit from the last veni-contracta B and into the outlet end.

When the diameter of the water column is increased, as required for increased foam volume as from 133 to 266 g. p. in., there may be a fourth or more upstream cone added to maintain the water column in streamline flow and effect homogeneous dispersion of the soap bubbles in the water to form the emulsion of foam. By adjustment of the inlet 5', the quantity of foam liquid may .be varied to `produce a foam mixture ranging from a freely running slush-foam to a non-running sponge-foam.

Water from the internal combustion engines pump enters the upstream cone under high pressure and at high velocity and passes in solid streamline flow, successively through the first.

-second and third throats of the ventura and sleeve Y which envelops the laminar stream nel circumscribing the throat or a circumferential annular channel. The soap liquid does not enter the Water, because of its very high velocity and streaming continuity, but as the soap liquid, at lower velocity, meets the water it is swept forward and is spread over the entire water circumferential area, forming a viscous liquid soap envelope moving forward with the water and it isv also in streamline forward fiow.

The now completely film-enveloped water and enveloping soap liquid together flow at high velocity through the second veni-contracta throat. Here again the absolute pressure is made very low which causes the gas final combustion products from the engine to enter, being led by a suitable `pipe to the exhaust gas inlet in the gas cone chamber'.

The exhaust gas on leaving the engine is normally at very high temperature and above atmospheric absolute pressure; however, the directional gas ow is to the place of its lowest absolute pressure which is at the second throat and this is placed after the directional plate-chambers through which the exhaust gas iiows in parallel. streamline with the water and liquid soap film enveloping both the foam-forming liquid and the water stream. During this first contact with the soap-film the hot gas is not cooled and is under a slightly decreasing pressure both of which prevents a material change in volume but causes the higher velocity gas and adhering foamforming liquid to adhere together as the gas is forced into the water through the liquid soap enveloping nlm by the increased pressure that follows the emergence of the three streaming uids together from the third veni-contracta throat into the discharge end. The hose-line then contains the compressed hot gas bubbles within parallel walls until the nre nozzle is reached. The water is forced under its very great velocity-head-pressure from the nozzle in streamline flow, carrying the exhaust gas bubbles in mixed suspension with a gas density greater than the surrounding atmospheric air. The bubbles have a surface tension greater than air formed foam together with a value of 7c, the thermal conductivity of the exhaust gas being only 0.0l81 as compared with 0.0265 for air.

The water is under forced high'pressure from its entry into the first upstream cone high-velocity head pressure until it leaves the fire nozzle. The velocity of the water is so great that it remains in streamline flow of circular transverse section without turbulence or circumferential splintering and very slight angular divergence until through. the third throatin which the gas film, in contact with the soap-liquid nlm, is slowed to attain the same velocity which is the velocity of the water.

In forced contact together lall at high initial velocity due to the differential low absolute pressure in which each exerts the force I,=MV

applies to each liquid and the gas, but W, which is the specific weight of unit volume, is different, i. e. the density of the three fluids is different and varies widely. Maintaining its streamline flow slower than the gas velocity because of its greater density the gas film adhering to the soap liquid is broken and shattered into very small bubbles; these are then dispersed by the resultant different velocity momentum forces into the Water stream.

The gas is at very high temperature `at the `time of disruption on the soap liquid to which 10 -it adheres. The exhaust gas bubbles, as formed and covered b y the soap liquid film, are forced into and dispersed through the Streaming Water. During this dispersal, the gas bubbles have their volume decreased only slightly by being cooled by the water, the time factor of the contact being too short to effect the temperature of the Water as it is limited to 0.0009 hr. During any contracting process, the soap liquid nlm covering the gas-spheres is thickened, thereby increasing the surface tension and contracting force exerted on each gas sphere. The resultant effect is that each bubble dispersed through the water stream has its density increased to such an extent that after projection in the water 4stream a distance of 100 ft. or more, at its very high temperature to the place of conflagration,

it is heavier than atmospheric air through which it is projected, and causes the hot-gas bubble blanket to lie on and continue to contract in volume as it cools and not ascend from the surface upon which it has been thrown and over which it has spread.

By the concentric streamline high velocity differential now, with the coldest liquid forming a core in the center and having the highest density and the hot exhaust gas at the outer circumference with the least density and highest temperature, the concentration of' mechanical foam-forming liquid per unit area of bubble surface is greater, thereby making the bubbles in the foam more stable both to heat and decreased pressure.

This method results in the attainment of uniform dispersion of a gas and of a liquid throughout another liquid by. first, enveloping, Without impact shock or turbulence, in successive lm layers, each fluid as it is admitted at high velocity, and directed and maintained in streamline forward and (-3) parallel ow i. e. without vector forces causing angular disruption or discontinuitv in the fluids to be dispersed or colloidalized into a homogenized state. Secondly, after each fluid annulus formed sleeve successively surrounds the actuating central liquid core, while all are moving in the same direction in absolutely parallel (I 3) and streamline flow but each at a different very high velocity relative to the other, there will be created, at each interface surface (gas to foam-forming liquid, foam-forming liquid to water), rotational motion within the contactingr surfaces as the faster moving surface draws with it the lm adhering to it. This non-vector, but only by parallel now force movement, creates a rotative movement, which in the foam-forming liquid is counterclockwise at the highest velocity or water surface, and clockwise in the foam-forming liquid at the gas face; but the rotational speeds are different due to difference in flow velocity, density adherence and viscosity. And third, only the liquid water stream maintains a constant for- Ward velocity passing through each successive Venturi throat without touching the metal surface thereof. But the velocity of the foam-liquid and the gas have their actual and relative velocities successively changed, greatly increased in each upstream cone and decreased after the throat. Therefore at no time are these velocities constant relative to each other or the Water stream before attaining the outlet end. Variable high velocity rotational nlm movement, caused by high velocity linear flow under successive variable gas-pressure heads, forces the gas into 11 bubble formation and dispersal through the high velocity water stream in which the gas bubbles are projected from the dihydro colloidal projector.

Another use of the device, and process encompassed by the invention resides in soil fertilization by colloidalized fertilizer and foam providing artificial snow-blanketing effects equal and better than natural. Greatly improved soil fertilization may be obtained by colloidal projected air fertilized foam made with liriuid fertilizing agents suit-able for the particular soil, such as slaked lime, phosphate, potash and other soil foods either alone or in suitable mixtures. Because, by this method of securing colloidal dispersion of the fertilizing agents with the air-aspirated, the very high oxygen content of the surface water is reduced by the pressure drop and is replaced by an equivalent volume of nitrogen received directly from the aspirated air. And when a protein base foamforming liouid (liouid soap formed from fats and oils) is used, the fertilizing air from colloidalized bubbles cover the soil. preventing Quick drying-out, and enabling the higher nitrogenized Water With both suspended and soluble fertilizing material to penetrate deeper without loss by evaporation. This longer time period secured for deep penetration of the carbon dioxide contained in the air-foam blanket by direct contact with the air carried into the earth with the bubbles is a reproduction of nature in effect to that equivalent to slow long-continued natural rain or winter snow.

Although certain specific Yembodiments, of the invention have been shown and described, it is obvious that many modifications thereof are possible. The invention, therefore, is not to be restricted except in so far as is necessitated by the prior art and by the spirit of the appended claims.

What I claim is:

1 A device for forming a colloidal mixture in a high velocity fluid stream without materially affecting the velocity thereof, which device comprises two Venturi-like tube portions vin axial alignment, each of said tube portions having upstream and downstream cones contracting to an intermediate throat, one of said tube portions having an axial inlet for the high velocity fluid and opening into the upstream cone for contraction of the fluid through the throat thereof to produce a rod-like stream of fluid, the other of said tube portions having an axial outlet opening from the downstreamrcone thereof, the forward edge portion of the upstream cone of said outlet tube portion surrounding the trailing edge of the downstream cone of said inlet tube portion to receive the high velocity rod-like stream of fluid therefrom, and an auxiliary inlet for each of said tube portions 3. A device as defined in claim 1 wherein an annular baflie is spaced from said downstream cone of the inlet tube portion to circumferentially distribute and streamline the flow of fluid through the inlet.

4. A device as defined in claim 1 wherein the inlet tube portion is formed in two parts, the primary of said parts including the axial inlet, upstream cone and throat with an internally threaded recess surrounding said throat and an inlet into the bottom of said recess, the secondary of said parts including the downstream cone and having external threads for adjustable insertion into said recess to define a selectively variable annular auxiliary inlet between said throat and said downstream cone.

5. A device as defined in claim 1 wherein the inlet tube portion is formed in two parts, the primary of said parts including the axial inlet, upstream cone and throat with an internally threaded recess surrounding said throat and an inlet into the bottom of said recess, the secondary of said parts including the downstream cone and having external threads for adjustable insertion into said recess to define a selectively variable annular auxiliary inlet between said throat and said downstream cone, said secondary part including means for rotating said part to thread it relative to said recess, and manually operable means extending through said primary part for actuating said rotating means.

6. A device as defined in claim 1 wherein said outlet tube portion comprising a first upstream cone open to the downstream cone of said inlet tube portion, and contracting to a terminal throat, a second upstream cone surrounding said terminal throat and contracting to a second throat which extends to the downstream cone, and another auxiliary inlet opening into said second upstream cone exteriorly of said rst upstream cone and terminal throat.

7. A device as defined in claim 1 wherein said outlet tube portion comprises a first upstream cone open to the downstream cone of said inlet tube portion, and contracting to a terminal throat, a second upstream cone surrounding said terminal throat and contracting to a second throat which extends to the downstream cone, and another auxiliary inlet opening into said second upstream cone exteriorly of said first upstream cone and terminal throat, said second throat and downstream cone being dimensioned relative to said terminal throat to define a streamlined phantom downstream cone for said terminal throat.

8. A multi-throat Venturi disperser for a water, foam mixture, comprising a body portion having an integral hyperboloid formed inlet section, a substantially cone-shaped throat integral with said body portion receiving the discharge of said inlet portion, the enlarged end ,of said throat portion encircling the outlet end.

of said inlet portion, a second cone-shaped throat portion carried in said body portion and receiving the discharge at its enlarged end from the first throat portion, the enlarged end of said second throat portion surrounding said first throat portion to define a vacuum chamber during operation, the said body portion being formed with a tapered restricted discharge end receiving the discharge from said second throat portion, the hyperboloidal-shaped inlet section being formed at its narrowest portion with a bypass for receiving a soap liquid and a second jacent said inlet, a pressure actuated injector 10 Number connected with the auxiliary inlet in said upstream cone, and a connection between said auxiliary outlet and said injector to supply iinid under pressure from said inlet to said injector 14 and actuate said injector to initiate flow through said auxiliary inlet.

CLINTON ROOT FOUTZ.

REFERENCES CITED The following references are of record in the le of this patent:

UNITED STATES PATENTS Name Date 2,146,605 Timpson Feb. 7, 1939 2,164,153 Friedrich June 27, 1939 2,198,585 Urquhart Apr. 23, 1940 2,361,980 Tyrrell Nov. 7, 1944 

